TY - JOUR
T1 - Submicrometer-sized NiO octahedra
T2 - Facile one-pot solid synthesis, formation mechanism, and chemical conversion into Ni octahedra with excellent microwave-absorbing properties
AU - Tong, Guoxiu
AU - Hu, Qian
AU - Wu, Wenhua
AU - Li, Wei
AU - Qian, Haisheng
AU - Liang, Yan
N1 - The authors thank the National Natural Scientific Foundation of China (Project no. 51102215), Natural Scientific Foundation of Zhejiang Province (Project no. Y4100022), the Key Innovative Team of Magnetic Materials in Zhejiang Province (Project no. 2011R09006-06), the Science and Technology Projects from Jinhua City (Project no. 2010A12066), and New Bud Talents Grant from Zhejiang Province.
Publisher copyright:
© The Royal Society of Chemistry 2012
PY - 2012/9/14
Y1 - 2012/9/14
N2 - A facile template-free and one-pot thermal decomposition approach was used for the mass preparation of submicrometer-sized NiO octahedra. Ni octahedra with tailored crystallization and texture characteristics are easily achieved through H 2-annealing of NiO octahedra at various temperatures. The good morphology retention of Ni octahedra is due to the principle of minimum surface free energy as well as the similar crystallographic system to that of NiO. Studies on static magnetic and microwave electromagnetic properties reveal the relationships among the reactivity, shape, and resultant properties of the nanomaterials. Because of their high BET specific surface area and favorable crystal size, porous Ni octahedra produced at 300 °C exhibit excellent matching and absorbing properties with a minimum R L value of -37.93 dB at 12.80 GHz and 11.60 GHz bandwidth (below -20 dB). Thus the Ni octahedra described here are believed to have a wide range of applications, including catalysis, electromagnetic shielding, and absorption.
AB - A facile template-free and one-pot thermal decomposition approach was used for the mass preparation of submicrometer-sized NiO octahedra. Ni octahedra with tailored crystallization and texture characteristics are easily achieved through H 2-annealing of NiO octahedra at various temperatures. The good morphology retention of Ni octahedra is due to the principle of minimum surface free energy as well as the similar crystallographic system to that of NiO. Studies on static magnetic and microwave electromagnetic properties reveal the relationships among the reactivity, shape, and resultant properties of the nanomaterials. Because of their high BET specific surface area and favorable crystal size, porous Ni octahedra produced at 300 °C exhibit excellent matching and absorbing properties with a minimum R L value of -37.93 dB at 12.80 GHz and 11.60 GHz bandwidth (below -20 dB). Thus the Ni octahedra described here are believed to have a wide range of applications, including catalysis, electromagnetic shielding, and absorption.
UR - http://www.scopus.com/inward/record.url?scp=84865021987&partnerID=8YFLogxK
U2 - 10.1039/c2jm31790g
DO - 10.1039/c2jm31790g
M3 - Journal article
AN - SCOPUS:84865021987
SN - 0959-9428
VL - 22
SP - 17494
EP - 17504
JO - Journal of Materials Chemistry
JF - Journal of Materials Chemistry
IS - 34
ER -
